The Regulatory Assistance Project 50 State Street, Suite 3 Montpelier, VT 05602
Phone: 802-223-8199 web: www.raponline.org
Module 6 Other Energy Issues, Developments,
and Emerging Technologies
August 15, 2011
Presented by Ken Colburn,
Christopher James, and John Shenot
Electric Energy Training for Air Regulatory & Planning Staff
US EPA OAQPS – August 15-16, 2011
Disclaimer
Presentations by non-EPA employees do not imply any official EPA endorsement of, or responsibility for, the opinions, ideas, data or products presented,
or guarantee the validity of the information provided. Presentations by non-EPA employees are
provided solely as information on topics related to environmental protection that may be useful to EPA staff and the public.
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Other Key Issues & Topics
• Consumption Trend
• “Smart Grid”
• Electrification of Transportation
• Energy Storage
• T&D Issues
• Distributed Generation (DG)
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NYNEX NG Forward Curve Snapshots
10/23/2008 ACTUAL LOCK
6/7/2009
8/13/2009
11/24/2009 E-pre
4/1/2010
4/28/2010 Settle
8/22/2010
12/1/2010
4-18-2011 Midday
6/24/2011 mid-day
8/5/2011 morning
• A Consumption Trend Inflection Point?
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Gas Forward Curve Has Continued Sliding Down
-2
0
2
4
6
8
10
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1950 1960 1970 1980 1990 2000 2015 2025 2035
While projected electricity consumption grows by 30% by 2035, the rate of growth has slowed
percent growth (3-year rolling average)
Projections
History
Period Annual Growth
1950s 9.8
1960s 7.3
1970s 4.7
1980s 2.9
1990s 2.4
2000-2009 0.5
2009-2035 1.0
Source: EIA, Annual Energy Outlook 2011
2009
U.S. Electricity Consumption
Source: CIA World Factbook, 2011, from http://www.indexmundi.com/g/g.aspx?c=us&v=81
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EIA Electric Power Annual (Rev April 2011)
• 2009 Year in Review:
– Electricity generation down 4.1%
• Lowest level since 2003
• Largest annual decline in 60 years
• Follows 0.9% drop in 2008
– Reflects 2.6% decline in economy (GDP)
– Delta = -1.5%; indicator of paradigm shift?
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• What is “Smart Grid”?
• An interconnected system of information and communication technologies that works with other technologies throughout the electricity system that can do good things: – Help utilities and consumers manage energy use
– Increase system reliability through automation – Improve integration of clean energy resources
• Distinguishing features of smart grid:
– (1) Engaging the customer, and
– (2) Integrating supply and demand
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Promise of Smart Grid
• Improved grid reliability, security and efficiency
• Timely information for consumers and new opportunities for saving energy and money
• Massive increases in demand response, energy efficiency, energy storage, distributed generation and large-scale renewable resources
• Electrification of the transportation sector
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Why Do Utilities Want Smart Grid?
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Increasing rate base is also certainly a driver.
Demand Response and Smart Grid
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Traditional DR
• Primarily utility control
• Focuses on a few end
uses
• Limited customer options
• Participation incentives
required
• Primary focus on retail markets
Smart Grid DR
• Customer control
• All end uses
• Unlimited options
• Advanced meters enable
dynamic pricing for all
• Wholesale and retail markets linked
Source: Levy, Goldman and Sedano
Consider Customer Resources in Distribution System Plans
• “Geo-target” energy efficiency, demand response, and distributed resources to reduce peak loads and defer distribution system upgrades
– Guidelines for considering cost-effective alternatives
– Incentives for investments in customer-side resources that can, together, defer costly
upgrades
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Clean Energy and Consumer Benefits Are Not Automatic
• Smart grid’s interconnected system of technologies can engage many quickly, but it’s only an enabler.
• Clean energy and consumer benefits require smart policies.
• Many policies should be adopted even without smart grid
investments. – Example: “Direct Load Control” by utilities (A/C, pool heaters, etc.)
• Without the right policies, smart grid is likely to divert attention and funds from clean energy investments that
can be made today.
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Smart Policies to Match Smart Capabilities: Examples
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Smart Capabilities Smart Policies
Allow interconnected
distributed generators to run
during utility outages
Support investments in clean distributed resources,
simplify interconnection requirements and procedures,
net metering, enable excess power sales
Dynamically integrate wind
and solar resources
Better planning for renewable resources and
transmission, support utility investments
Continuous building
diagnostics
Invest in efficiency programs for buildings and major
energy-consuming equipment for all customer classes
Optimize voltage and
reactive power
Remove barriers for utility investments to improve
distribution system efficiency
Increase demand response Supportive rates or incentives, consumer access to
energy usage data, support for automated controls
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• Electrification of Transportation Non-Road Equipment Examples
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Source: EPRI 2011 Technical Report, Transportation Electrification Technology Overview.
Penetration of PEVs
Scenarios: Low based on past sales; Medium based on “ground up” estimates; High based on forecasts.
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Source: EPRI 2011 Technical Report, Transportation Electrification Technology Overview.
Gasoline Savings & CO2 Reductions
Scenarios: Low based on past sales; Medium based on “ground up” estimates; High based on forecasts.
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Source: EPRI 2011 Technical Report, Transportation Electrification Technology Overview.
Electricity Consumption and Timing
Scenarios: Low based on past sales; Medium based on “ground up” estimates; High based on forecasts.
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Source: EPRI 2011 Technical Report, Transportation Electrification Technology Overview.
Smart Grid Integration Crucial
Integrated Load Management
Storage for Peak
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• Electricity Storage
• Why Storage? (demand vs. generation timing, cost, source variability (e.g., RE))
• Evolution of Electricity Storage (pumped storage)
• New Capabilities Provided by Advanced Storage
Technologies
• Application Areas for Advanced Electricity Storage
• Supporting Renewable Deployment and Emission
Reductions
• Smart Grid - Key to Full Utilization of Electricity Storage
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Electricity Storage Applications
• Generation Applications – Regulation or Automatic Generation Control Service – Primary or Governor Response – Real-time Dispatch/Balancing Energy – Renewables Balancing – Diurnal and Longer Time Shifting – Reserves; Distributed Generation
• Transmission & Distribution – Voltage Support – Transmission Time/Load Shifting – Stability-Related Applications – Transmission/Distribution Deferral – Radial System Reliability Improvement
• Electrification of Transportation
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Electricity Storage Technologies (Examples)
• Batteries – Lead-Acid – Nickel-Cadmium and
Nickel-Metal Hydride – Lithium-Ion – Sodium-Sulfur (NaS) – Zinc-Bromine – Vanadium Redox
• Flywheels
• Compressed Air (CAES)
• Pumped Hydro; Ice
• More Technologies
in Development
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• Largely discussed previously (e.g, losses)
• Technology rapidly developing
• Example: Wireless PEV recharging (BMW & Siemens;
others)
• Transmission & Distribution Issues
• Distributed generation (DG) is the use of smaller-scale power generation technologies located close to the load
being served.
• For many customers, DG can lower costs, improve
reliability, reduce emissions, or expand their energy options.
• DG stakeholders include energy companies, energy
users, regulators, equipment suppliers, and financial and supporting companies.
• Only 0.5% of U.S. electric generation in 2000, expected to be 11% of capacity additions through 2025 (CBO, EIA)
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• Distributed Generation (DG) - Definition
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• Technologies New small-scale, efficient power generation technologies are promising to provide
generating performance that previously was available only from large central station plants
• Customer Needs – Changes in electric customer needs for power reliability are creating an increased value for high quality power.
• Restructuring – Electric utility restructuring is creating new opportunities for self-generation as well as concerns
over the future cost and/or reliability of the central power generating system.
DG Drivers
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• Typical today: – Internal Combustion Engines – Combined Heat & Power
– Wind Turbines – Microturbines – Fuel Cells
– Photovoltaics – Anerobic Digestion
• Note: Emissions vary greatly; heavy interplay
with RE
DG Technologies (1)
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• Rapidly developing new technologies and improvements: – Tidal and wave energy – Thermo-electric effect (Chen, MIT & Ren, BC) – Fast-charging batteries (Braun, UI-UC)
– PV efficiency (e.g, silver scattering)
• “Next Great Decentralization” – As already seen in computing, telephony – Will see both supply-side and demand-side innovation
– Will policies obstruct or encourage?
DG Technologies (2)
Question & Answer Period
• Thank You!
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About RAP
The Regulatory Assistance Project (RAP) is a global, non-profit team of experts that focuses on the long-term economic and environmental sustainability of the power
and natural gas sectors. RAP has deep expertise in regulatory and market policies that:
Promote economic efficiency
Protect the environment Ensure system reliability
Allocate system benefits fairly among all consumers
Learn more about RAP at www.raponline.org
Ken Colburn, Senior Associate
617-784-6975
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Additional Slides
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Smart Grid Discussion Questions
• How should we frame smart grid with decision-makers? – How do we get our main theme (smart policies before
smart grids) across to key players?
– What other themes and policy ideas should RAP pursue?
• What are the most important actions regulators can take to guide smart grid toward energy and carbon savings?
• What are the key opportunities and venues for RAP to get results?
• What smart grid issues are hot in the EU and India?
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• What’s the timing of key decisions for smart grid investments and requisite policies?
• How can we better engage consumers? – Where have utilities and regulators gone? – As we move ahead, how can we engage
customers effectively?
• What’s the role of utilities vs. third parties? • How should we pay for utility investments
needed to get smart grid-enabled savings? – What’s gone wrong – and right – with utility
cost recovery processes?
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Smart Grid Discussion Questions (2)
• What’s needed to make dynamic pricing programs successful? – Success = $ savings for participants and
ratepayers overall, carbon reductions, helping to integrate variable renewable energy resources, what else?
• How do coal plant retirements fit in? – As natural gas and renewables help fill in, demand response
should yield cleaner results and will help integrate variable renewable energy resources. Should we make this link?
• What are RAP’s next steps? – Research, papers, meetings, public forums, areas where we
need to further develop our thinking, etc.
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Smart Grid Discussion Questions (3)
“BHAG” vs. the Cost of Saved Energy
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Integrate Smart Grid With Rate Design and Demand-Side Programs
• Smart grid allows customers to become more involved in how and when they use energy. – They won’t respond just because they get shiny new
meters.
• Let customers choose a dynamic pricing option that varies according to market prices and system conditions. – Rates that reduce utility costs, encourage long-term
reductions in peak loads and support distributed resources
• Make it easy for customers – Controls that respond
automatically to prices
• Right-time charging and discharging of electric vehicles 37
Customers
Rate design
and pricing
Utility system
Energy Efficiency and Smart Grid
• Optimize voltage and reactive power on distribution systems
– Reduced line losses and energy use in homes and businesses
• Continuous building diagnostics
– Alert owners about problems with energy-consuming equipment 38
Renewable Resources and Smart Grid
• Improved integration – Awareness of grid conditions
– Fast operational changes
– Voltage support
– Monitor line loading and wind turbine curtailment
• More system flexibility – Demand response – Decrease and increase loads
– Energy storage
– Plug-in electric vehicles – Charge when wind levels are high, provide energy storage, provide ancillary services
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Distributed Resources and Smart Grid
• Intelligent sensors, software, two-way communications, and advanced controls can dynamically integrate distributed generation and energy storage with other resources – and loads – Minimize losses, provide voltage
support and improve reliability
• Microgrids – Interconnected network of loads, generation, and energy storage that works connected to or separate from grid
Plug-in electric vehicles Charge off-peak
Provide energy storage and ancillary services
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• Information-driven
behavior changes – Data from smart meters
and smart thermostats
– Customized analysis, comparisons, and recommendations to consumers via Web, in-premise devices, phone, e-mail or snail-mail
• Better evaluation – Less money needed for
analysis, more money spent on measures
41 Source: Chris King, eMeter Strategic Consulting